Automated data analysis

ABSTRACT

A compatibility of a computational analysis and a data set is automatically determined by comparing data set attribute data with attribute data of the computational analysis. Other computational analyses may also be evaluated for compatibility with the data set. Compatible analyses may be performed on the data set, and selected views of the results may be presented. Selection of the analyses to be performed, the views, and/or the contents and format of the views may be determined based result data attributes and computational analysis attribute data as well as other considerations, such as resources required and multiplicity. As computational analysis attributes are based on a set of rules or statements determined from heuristics of respective computational analyses, evaluation of the compatibility between various analyses and the data set is accordingly determined based on the heuristic-based rules or statements. Computational analyses may include visualizations and heavyweight computational analyses.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No. 13/763,568 (now U.S. Pat. No. 9,355,160), entitled “Automated Data Analysis,” filed on Feb. 8, 2013, which is hereby incorporated by reference in its entirety.

BACKGROUND

Data analysis tools and systems typically allow a user to input or enter a data set, such as by uploading a file to the system or, in some cases, by manually inputting data points or data values. The user may then select various visualizations of the data set provided by the tool or system to glean information about the data.

One such data analysis system is the Many Eyes Project of International Business Machines Corporation (IBM). The Many Eyes system allows users to upload data sets, perform visualizations on their own data sets or data sets uploaded by others, and share and comment on insights that the users observe from the various visualizations. The Many Eyes system requires a data set to follow specific formatting rules in order for a data set to be successfully uploaded and interpreted. For example, a data set must have a header describing the identity or context of the data to enable the Many Eyes system to correctly set up and label the visualizations. The header must be placed in the initial row of the data set, and the data set cannot include multiple header rows. Other rules and constraints on input data format are required by the Many Eyes Project system, e.g., all rows must be of the same length, and summary (e.g., total) rows must be deleted if the user does not want a summary row to be considered by the Many Eyes Project system as yet another distinct row of data values.

After a data set is uploaded into the Many Eyes system, a user may select one of a set of visualizations to perform on the uploaded set. For example, the Many Eyes Project system provides visualizations such as scatterplots, matrix charts, network diagrams, bar charts, block histograms, bubble charts, line graphs, stack graphs, stack graphs-by-categories, pie charts, tree maps, tree maps-for-comparison, word trees, tag clouds, phrase nets, and word cloud generators. A user selects which of these visualizations that he or she desires to be utilized with the uploaded data set.

Another example of data analysis tools or systems are the commercially available Tableau® Software products. Tableau asks a user to identify the format of the input data by selecting one of a set of known formats that are supported by Tableau (e.g., Microsoft® Excel, Cloudera® Hadoop Hive, IBM DB2, etc.). Once the data set is uploaded, the user drags and drops a column or a row of the uploaded data to a particular desired column or row of a Tableau-format data working space. Alternatively, a user may manually enter data by piecewise pasting data into rows or columns of the Tableau-format data working space.

Once a Tableau-format data set has been designated and generated by the user, the user selects one of a set of views to be applied to the Tableau-format data set. Similar to the Many Eyes Project, Tableau provides a suite of possible views from which the user makes a selection, e.g., data distribution graphs, scatter plots, bubble charts, geographical distributions, or bar charts.

Accordingly, the Many Eyes Project, Tableau Software, and other such data analysis tools and systems typically require that an object data set have a given, particular data set format in order to be properly interpreted. Furthermore, the selection of the views or visualizations to be performed on the uploaded data set is entirely directed by the user.

SUMMARY

In an embodiment, an automated data analysis system for automatically determining compatibility between a computational analysis and a target data set includes one or more tangible, non-transitory computer readable storage devices on which computational analysis attribute data is stored. The computational analysis attribute data comprises information or data that indicates one or more respective attributes of each computational analysis of a set of computational analyses, and the attributes of each computational analysis indicate characteristics or properties of data that is compatible with each computational analysis. That is, when a computational analysis is performed on data having the characteristics and properties reflected by the attributes of the computational analysis, a meaningful, useful, statistically interesting, or rich result is generated.

The one or more tangible, non-transitory computer readable storage devices are communicatively coupled to one or more computing devices storing computer-executable instructions, that when executed by a processor, cause the one or more computing devices to receive data set attribute data corresponding to a target data set. The data set attribute data comprises information or data indicative of one or more attributes of the target data set. The one or more computing devices may perform a comparison of the data set attribute data and computational analysis attribute data corresponding to a particular computational analysis of the set of computational analyses, and may determine a measure of compatibility between the target data set and the particular computational analysis based on the comparison. Further, the one or more computing devices may select a subset of one or more computational analyses from the set of computational analyses based on the measure of compatibility corresponding to the particular computational analysis, where the selected subset of the one or more computational analyses are to be performed on at least a portion of the target data. Additionally or alternatively, the one or more computing devices may cause an indication of the measure of compatibility corresponding to the particular computational analysis to be transmitted to another system or computing device, such as a user computer.

In another embodiment, a method for automatically analyzing data sets to determine compatible computational analyses includes receiving, via a communication link at one or more computing devices, data set attribute data, where the data set attribute data comprises information or data indicative of one or more attributes of a target data set. The method may also include performing a comparison of the data set attribute data and computational analysis attribute data corresponding to a particular computational analysis. The particular computational analysis may be one of a plurality of computational analyses, the computational analysis attribute data of the particular computational analysis may comprise information or data that is indicative of one or more attributes of the particular computational analysis, and the attributes of the particular computational analysis may indicate characteristics or properties of data with which the particular computational analysis is compatible. That is, when the particular computational analysis is performed on data having the characteristics or properties indicated by the attributes of the particular computational analysis, a meaningful, useful, statistically interesting, or rich result is generated.

The method also includes determining a measure of compatibility between the target data set and the particular computational analysis based on the comparison. Additionally, the method includes at least one of (i) selecting a subset of one or more computational analyses from the plurality of computational analyses based on the measure of compatibility corresponding to the particular computational analysis, where the selected subset of one or more computational analyses is to be performed on at least a portion of the target data set, or (ii) causing an indication of the measure of compatibility between the target data set and the particular computational analysis to be generated at a user interface.

In yet another embodiment, a system for supporting a data analysis includes a plurality of indication sets stored one or more tangible, non-transitory data storage devices. Each indication set includes indications of computational analysis attributes of a particular computational analysis of a plurality of computational analyses. The computational analysis attributes of each computational analysis indicate data characteristics or properties whose presence is necessary for data to be compatible with the computational analysis. Additionally or alternatively, the computational analysis attributes of each computational analysis indicate data characteristics or properties whose presence is preferred or sufficient for data to be compatible with the computational analysis.

The system for supporting a data analysis further includes an interface to the one or more tangible, non-transitory computer readable storage devices via which one or more computing devices are communicatively coupled. The one or more computing devices are configured to provide at least some of the indication sets to a data analysis system, where the data analysis system performs at least some of the plurality of computational analyses based on at least some of the indications included in the provided indication sets.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an example system for automatically analyzing a data set, according to an embodiment;

FIGS. 2A and 2B are an illustrative and non-limiting list of lightweight and heavyweight computational analyses that may be performed on a target or object data set, according to an embodiment;

FIG. 3 illustrates a portion of the contents of a sample data set used in an illustrative scenario employing the example system of FIG. 1;

FIGS. 4A-4B and 5A, 5B-1, 5B-2, 5C-1 and 5C-2 illustrate example displays that may be generated at a user interface by the example system of FIG. 1 in the illustrative scenario; and

FIG. 6 is a flow diagram of an example method that may be implemented by the example system of FIG. 1, in an embodiment.

DETAILED DESCRIPTION

Embodiments described herein may be utilized in a system for automated data analysis. The automated data analysis (ADA) system may receive a target or object data set, and the system may analyze the provided data set to determine contexts of and relationships among the data points or data values included therein. Based on the determination of the contexts and relationships among the data values, and without requiring any user input (at least in some embodiments), the system may automatically (at least in some embodiments) determine a set of suitable or compatible computational analyses to apply to the data set, e.g., a set of computational analyses that, when performed on the data set, generates rich, meaningful, useful and/or statistically interesting results. The determination of the set of suitable or compatible computational analyses may be based on a comparison of attributes of the data set with attributes of various computational analyses. In some embodiments, the determination of the set of suitable or compatible computational analyses may also be based on previously performed data analyses, resource usage, previous or current user actions, user input, and/or other suitable or desired factors.

In some embodiments, after determining the set of suitable or compatible computational analyses for the provided data set, the automated data analysis system may present identifications of at least some of the suitable or compatible computational analyses to a user. In some embodiments, the system may automatically apply at least some of the one or more computational analyses to the data set, and may present corresponding results to the user. Typically, the reception of the target data set, the determination of the set of suitable or compatible computational analyses, the execution of at least some of the set of suitable or compatible computational analyses, and/or the generation and display of the results of the executed analyses, in some embodiments, is accomplished by the automated data analysis system in a real-time manner and/or with a reasonably short delay.

FIG. 1 is a block diagram of an example system 100 for automatically analyzing a data set, according to an embodiment. The system 100 includes an automatic data analysis (ADA) system 102. As described in more detail below, the ADA system 102 is configured to automatically analyze a data set and to automatically determine, at least in some embodiments, suitable and/or compatible computational analyses that, when applied to the data set, provide rich, meaningful, useful or statistically interesting results. The system 100 may include a user computer or computing device 105 communicatively coupled to the ADA system 102 via a communication network 108. The communications network 108 may include one or more of a local area network (LAN), a wireless LAN, a wide area network (WAN), a mobile communications network, the Internet, or any other suitable public or private wired or wireless communication network.

In an embodiment, a user may input, upload or identify an original data set 110 a via a user interface at the computing device 105. The user interface may be included in, for example, a web interface or a client of the ADA system 102 executed by one or more processors of the computing device 105. The original data set 110 a may be delivered from the computing device 105 via the network 108 to the ADA system 102, in an embodiment. The original data set 110 a may be referred to herein as a “target” or “object” data set on which the ADA system 102 may operate, and the original data set 110 a may be interchangeably referred to herein as an input data set to the ADA system 102.

The original data set 110 a may include a set of data 112 a. The data 112 a may include natural language characters or strings, the data 112 a may include symbolic language such as numeric or alphanumeric characters and expressions, and/or the data 112 a may include graphs, images, and other types of data. The data 112 a may be arranged in any structured or semi-structured format. However, for the data 112 a of the original data set 110 a to be operated on by the ADA system 102, the ADA system 102 need not have a priori knowledge of the structure of the original data set 110 a, in some embodiments. Indeed, not only does the ADA system 102 not need to know the structure of the original data set 110 a, the original data set 110 a is not required to include (e.g., may exclude) any information that identifies the contexts, identities, or categories of the data values, such as a header or labels, in some embodiments and/or scenarios. Instead, the ADA system 102 may analyze the data 112 a and their interrelationships, and may automatically determine the contexts, identities, or categories of the data 112 a based on the analysis. As such, the original data set 110 a is not required to be of a known database or spreadsheet format at all, such as Microsoft Excel, SQL, Hadoop, etc., in some embodiments.

Generally speaking, the data 112 a included in the original data set 110 a may only be required to be, at a minimum, arranged or grouped in some consistent manner so that the ADA system 102 is able to determine or deduce a structure of the original data set 110 a, in an embodiment. That is, the input data set 110 a is only required to be in a consistent, structured or semi-structured arrangement, in some embodiments. Nonetheless, if the original data set 110 a does include context or category information, the ADA system 102 may still be able to properly interpret the data values of the data set 110 a, in some embodiments. Indeed, the original data set 110 a may include any number of header rows or columns that include context, identity, and/or category information, such as zero, one, two, or more header rows and/or columns.

In an embodiment, a pre-processor 115 of the automated data analysis system 102 may receive the original data set 110 a, analyze the data 112 a of the original data set 110 a and their interrelationships, and automatically determine contexts, identities, relationships, categories and/or structure(s) of the data 112 a within the data set 110 a based on the analysis. For example, the pre-processor 115 may analyze the data 112 a of the original data set 110 a to determine one or more groupings, sets, or subsets of data values therein that are contextually related. Each grouping of data values may be contextually related, structurally related, and/or related in some other manner. For example, a grouping of data 112 a of the original data set 110 a may correspond to a struct or a structure of the original data set 110 a, such as one actual column of data values, more than one actual column of data values, one actual row of data points, more than one actual row of data values, an actual column and an actual row of data values, or all data of the original data set 110 a (e.g., all the data 112 a). Additionally or alternatively, a grouping of the original data set 110 a may include a list of data values, a hierarchy of data values (e.g., Extensible Markup Language (XML)), a collection of data values, a random set of data values, a graph (e.g., a set of vertices and edges), or any other data 112 a that are related by context, structure, and/or in some other manner. In some scenarios, a particular grouping may itself include a plurality of groupings or sub-groupings. To illustrate the term “grouping,” an entire set of data values of an example data set of banking information may be a first grouping of the example data set, a second grouping of the example banking information data set may be customer information, a third grouping may be account numbers, a fourth grouping may be account balances, and a fifth grouping of the example data set may be dates.

Returning to FIG. 1, based on the analysis of the data 112 a of the original data set 110 a, the pre-processor 115 may determine a number of groupings of the original data set 110 a and the identity or context of each grouping. For example, the pre-processor 115 may determine one grouping, two groupings, or more than two groupings and their respective identities, contexts, or relatedness. In some cases, a particular data value may be included in more than one grouping. That is, the groupings of a data set are not required to be mutually exclusive sets.

Accordingly, in an embodiment, the pre-processor 115 may determine a converted data set 110 b from the original data set 110 a, where the converted data set 110 b includes the data values 112 b, the contexts or identities of one or more groupings or sets of the data values 112 b, a respective indication of which of the data values 112 b are included in each grouping, and information or data 118 that is indicative of attributes of the converted data set 110 b. The information or data 118 indicative of the attributes of the converted data set 110 b is interchangeably referred to herein as “data set attribute data 118” of the converted data set 110 b. In an embodiment, at least a portion of the data set attribute data 118 may be metadata. A particular datum of the data set attribute data 118 may be indicative of one or more attributes of the converted data set 110 b, in an embodiment.

The data set attribute data 118 may identify one or more attributes of the converted data set 110 b, and/or may describe one or more attributes of the converted data set 110 b. The data set attribute data 118 may define one or more attributes of the data set 110 b, in some embodiments, and/or may suggest one or more attributes of the data set 110 b, in some embodiments. In some embodiments, the data set attribute data 118 may correspond to one or more attributes of the converted data set 110 b. In some embodiments, the data set attribute 118 may be associated with one or more attributes of the converted data set 110 b.

An “attribute” of the converted data set 110 b (or a “data set attribute” of the converted data set 110 b, as used herein), generally refers to a characteristic or property of the converted data set 110 b or of at least a portion of the data 112 b included therein. For example, a data set attribute of the data set 110 b may be a statistical or semantic property of a grouping of the data set 110 b. Examples of data set attributes may include a type of the data values in a grouping (e.g., labels, entities, decimal numbers, floating point numbers, binary numbers, etc.); whether the data values of a grouping are serially correlated; whether all of the data values of a grouping are of the same length; whether an interval between successive data values of a grouping is constant; whether the data values of a grouping are randomly or uniformly distributed; a range of the data included in a grouping; an indication of other types of data values or objects with which the data values of a grouping may be combined; an indication of transformations that may be applied to a grouping; and other suitable data set attributes.

Referring again to the banking information data set example as an illustration, an attribute of the grouping “account balance” may be that the data values of “account balance” each have a numerical format with a decimal point, with any number of digits to the left of the decimal point and with two or less digits to the right of the decimal point. An attribute of a grouping “customer tax identification number” may be that the data values of “customer tax identification number” each have a nine digit numerical format ABC-DE-FGHI or ABCDEFHI. An attribute of a grouping “customers” may indicate that at least some data values included therein have at least two alphabetical strings <<FirstName>> <<LastName>>.

In an embodiment, the pre-processor 115 may perform only a subset of the pre-processor capabilities and functionalities discussed herein. For example, while the pre-processor 115 discussed above has the capability to automatically determine the contexts or identities of the data 112 a by analyzing the contents and the interrelationships of the data 112 a, if the original data set 110 a does include headers, the pre-processor 115 may use the headers of the original data set 110 a to determine the contexts or identities of the data 112 a without analyzing the contents and the interrelationships of the data 112 a.

In an embodiment, the ADA system 102 is operable with pre-processors other than the pre-processor 115. For example, the ADA system 102 may receive a data set from a prior art type of pre-processor that is only able to operate on data sets of approved, specific input file formats. As another example, the ADA system 102 may receive a data set from a prior art type of pre-processor that requires user input to define the structure of the data set (e.g., user input specified columns), the types of data in the data set, etc. In another embodiment, a pre-processor (whether the pre-processor 115 or another pre-processor) may be omitted from the ADA system 102 altogether.

The data set attribute data 118 of the converted data set 110 b may be provided to the matching engine 120, e.g., by the pre-processor 115, or directly by the network 108 in embodiments without the pre-processor 115. The matching engine 120 may receive the data set attribute data 118, and may compare the data set attribute data 118 with information or data 128 that is indicative of attributes of a set of computational analyses 125 a-125 n (also referred to interchangeably herein as “computational analysis attribute data 128”). For example, the computational analysis attribute data 128 may include one or more indication sets 122 a-122 n, each of which may be indicative of one or more attributes of a respective computational analysis 125 a-125 n that may be performed on or applied to an object or target data set. For example, computational analysis attribute data that is indicative of attributes of the computational analysis 125 a may be stored in indication set 122 a, and computational analysis attribute data that is indicative of the attributes of the computational analysis 125 b may be stored in indication set 122 b. In an embodiment, at least some of the computational analysis attribute data 128 may comprise metadata.

Each indication set 122 a-122 n may identify one or more attributes of a respective computational analysis 125 a-125 n, and/or may describe one or more attributes of the respective computational analysis 125 a-125 n. Each indication set 122 a-122 n may define one or more attributes of the respective computational analysis 125 a-125 n, in some embodiments, and/or may suggest one or more attributes of the respective computational analysis 125 a-125 n, in some embodiments. In some embodiments, each indication set 122 a-122 n may correspond to one or more attributes of the respective computational analysis 125 a-125 n. In some embodiments, each indication set 122 a-122 n may be associated with one or more attributes of the respective computational analysis 125 a-125 n.

The ADA system 102 may store or have access to the computational analysis attribute data 128. In an embodiment (not shown), at least a portion of the computational analysis attribute data 128 may be stored with respective computational analyses 125 a-125 n of a set of computational analyses 130, e.g., the computational analysis attribute data 128 and the set of computational analyses 130 may be (at least partially) integrally stored. In another embodiment, the computational analysis attribute data 128 may be stored separately from any actual computational analyses 125 a-125 n. For example, as illustrated in FIG. 1, the actual computational analyses 125 a-125 n (or the executable instructions corresponding thereto) may be stored separately 130 from the computational analysis attribute data 128, however, the computational analyses or executable instructions corresponding thereto (reference 130) may still remain accessible to the ADA system 102, such as via a communication interface. Further, while in FIG. 1 the computational analysis attribute data 128 is shown as being included in the ADA system 102, in some embodiments, the computational analysis attribute data 128 is excluded from or not integral to the ADA system 102, but is nonetheless accessible to the ADA system 102 via a communication interface.

Based on the comparison of the data set attribute data 118 with the computational analysis attribute data 128, the matching engine 120 may determine one or more suitable and/or compatible computational analyses for the converted data set 110 b, such as a subset of the computational analyses 125 a-125 n. The identity of the one or more suitable and/or compatible computational analyses may be presented at the user interface of the computing device 105, e.g., via the network 108. In some embodiments, one or more of the suitable or computational analyses 125 may be automatically performed by the ADA system 102 on the converted data set 110 b to generate a result, and the result may be presented at the user interface of the computing device 105. The aforementioned determination of compatible computational analyses and data sets is described in more detail below after an explanation of various terms used herein is provided.

A “computational analysis,” as used herein, generally refers to one or more computing actions or computations that may be performed on, applied to, executed on, or operated on at least a portion of data values included in an object or target data set. For example, a computational analysis may be applied to an entire object data set as a whole, or to one or more groupings of the object data set. An execution of a computational analysis on a data set may be interchangeably referred to herein as the data set being transformed by the computational analysis. Each computational analysis may be implemented as a set of machine readable instructions that, when executed by one or more processors, perform the computational analysis on a set of input data.

Note that while a computational analysis may perform a mathematical or computing action, the result of a computational analysis need not be expressed in a computational, graphical, or numerical language. For example, a phrase net computational analysis uses computational pattern matching to determine relationships between words in a text, but the output of a phrase net analysis may only display the words of the text and differently-sized pictorial arrows showing the interrelationships of the words.

Some computational analyses supported by the ADA system 102 may be relatively simple or lightweight. Examples of simple or lightweight computations are “views” or “visualizations.” Examples of visualizations include scatter plots, matrix charts, network diagrams, bar charts, block histograms, bubble charts, line or stack graphs, stack graphs for categories, pie charts, tree maps, tree maps for comparisons, word trees, tag clouds, phrase nets, word cloud generators, and geographical map distributions, and the like. Other examples of lightweight computations are calculating an average of a group of numbers, calculating a standard deviation of the group of numbers, etc.

Other computational analyses supported by the ADA system 102 may include more complex or heavyweight computational analyses. Typically, when a complex or heavyweight analysis is performed on a first data set, a second data set different from the first data set (as contrasted with a mere visualization of the first data set) may be generated. Examples of such complex or heavyweight computational analyses may include various different types of integration, differentiation, Fourier analysis, symbolic manipulation and numeric analysis, regression, symbolic matrices, numerical discrete calculus, logic and Boolean algebraic analyses, N-dimensional computations, etc. FIGS. 2A and 2B provide a detailed and non-limiting list of possible lightweight and heavyweight computational analyses that may be supported by the ADA system 102.

A “computational analysis attribute” (e.g., an “attribute” of a computational analysis) may indicate a characteristic or property of the computational analysis itself. Additionally or alternatively, an attribute or computational analysis attribute of a particular computational analysis may indicate a characteristic or property of an object data set that is compatible with the particular computational analysis, e.g., an object data set that, when transformed by the particular computational analysis, generates a meaningful or useful result (e.g., a statistically meaningful result). As such, an “attribute” of the particular computational analysis may indicate a constraint on one or more inputs to the particular computational analysis. Generally, computational analysis attributes corresponding to a particular computational analysis may be based on a set of rules or statements that are generated or determined from heuristics of the computational analysis and of data sets operated on by the computational analysis over time. One of many examples of such a rule or statement based on heuristics may be “the closer the value of a coefficient of determination (R²) generated by a regression computational analysis on a data set is to one, the more compatible the data set is to the “regression” computational analysis.”

An example of a computational analysis attribute may be an indication of the lengths of time to perform the computational analysis on inputs of differing or increasing lengths, e.g., a result of an asymptotic analysis of the computational analysis to determine limiting behavior. Another example of a computational analysis attribute may include an indication of how the analysis parallelizes, e.g., an indication of how suitable the computational analyses is for being performed using a set of multiple, concurrent sub-operations. Other examples of attributes of computational analyses may include a parameter that is required as an input to the computational analysis before the computational analysis is operable, a type or data type of the input on which the computational analysis is operable, a linguistic form of a required parameter or input, a type or data type of an output generated by an execution of the computational analysis, and other suitable computational analysis attributes.

A computational analysis attribute may be a required attribute or a preferred (e.g., sufficient) attribute. For example, for a Fourier series computational analysis, a suitable or compatible set of target or object data values is required to have data spaced at uniform time intervals. On the other hand, a preferred or sufficient (but not required) attribute of the Fourier series computational analysis is a set of target or object data values having a non-random distribution. For example, a Fourier series computational analysis of randomly distributed data will likely produce an uninteresting result, while a Fourier series analysis of non-randomly distributed data is likely to produce a more interesting result, based on an example associated rule derived from heuristics. Accordingly, a required attribute of a particular computational analysis may be a necessity for the particular computational analysis to execute, whereas a preferred attribute or a sufficient attribute may be an option that increases the likelihood that the particular computational analysis will produce a useful and/or interesting result.

Additionally, a computational analysis attribute may be functional or parametric. Whether or not a target data set comports (at least partially, if not entirely) with a functional attribute of a computational analysis may be determined by executing a function on data set attribute data that corresponds to the target data set, or that corresponds to a grouping of data values included in the target data set. For example, at least a portion of data set attribute data corresponding to a target grouping may be input into a function associated with the functional computational analysis attribute. In an embodiment, the function corresponding to the functional computational analysis attribute may be indicated by the functional computational analysis attribute data. The resulting output of the function may indicate if (and/or the extent to which) the target grouping comports (at least partially, if not entirely) with the functional attribute of the computational analysis.

Using an example time series computational analysis to illustrate, an example of a preferred attribute for a time series computational analysis is for the data values to be non-randomly distributed, e.g., having some underlying characteristics of smoothly varying values over time and/or having patterns that repeat over time. To determine whether or not a target grouping comports with the “non-random distribution” attribute, data set attribute data corresponding to the target grouping may be input to a functional calculation corresponding to the “non-random distribution” attribute of the time series computational analysis. The output of the functional calculation may include an indication or measure of the non-randomness of the data values of the target grouping, and the indication or measure of the non-randomness may be used to determine the measure of compatibility between the computational analysis and the data set in which the target grouping is included.

On the other hand, in contrast to a functional attribute, a parametric attribute of a computational analysis may be a characteristic that can be compared to an already-determined attribute of a grouping of data values. As an illustrative example, a parametric attribute of a computational analysis may be a requirement that the target data set include only non-negative numeric values.

Some computational analyses may be applied to multiple groupings or sets of data values included a data set. Accordingly, computational analysis attributes may correspond to attributes of multiple groupings of a data set. For example, a regression computational analysis may be applied to two or more groupings of data values of a data set, and a computational analysis attribute for the regression computational analysis may be that each target grouping of data values have the same number of data values.

Returning to FIG. 1, the computational analysis attribute data 122 a-122 n may include information or data that is indicative of required attributes, preferred or sufficient attributes, functional attributes, parametric attributes, and/or other types of computational analysis attributes. As such, for a particular computational analysis, a target grouping that has more data set attributes comporting with preferred computational analysis attributes (as indicated by respective attribute data) may be considered to be more suitable or compatible for the particular computational analysis than is another target grouping that has less data attributes comporting with the preferred computational analysis attributes (as indicated by respective attribute data). A particular computational analysis may be evaluated, using attribute data comparison, for compatibility with different sets of target or object groupings of the data set 110 b.

As discussed above, in an embodiment, the matching engine 120 may determine a measure of compatibility and/or suitability of the data set 110 a to a particular computational analysis (e.g., computational analysis 125 a) based on a comparison of at least a portion of the data set attribute data 118 and at least a portion of the computational analysis attribute data (e.g., computational analysis attribute data 122 a). The measure of compatibility may represent a degree of compatibility between the particular computational activity and the data set 110 a. In an embodiment, a range of the measure of compatibility may be binary, e.g., incompatible and compatible. In an embodiment, a range of the measure of compatibility may be continuous over more than two absolute values, e.g., a range of zero to 100 with zero representing incompatible and 100 representing perfect or near-perfect compatibility. In an embodiment, the measure of compatibility may be represented by a probability or by another statistical format. For example, the measure of compatibility may include a probability of incompatibility between the particular computational analysis and the data set 110 a, or may include a probability of compatibility between the particular computational analysis and the data set 110 a. Accordingly, in view of the above, a measure of compatibility may include an indication of a measure of incompatibility (e.g., the converse of a measure of compatibility may be the measure of incompatibility).

In some embodiments, the measure of compatibility and/or suitability may also be based on one or more other compatibility criteria, such as a time required to execute the particular computational analysis 125 a on the data set 110 b, on a portion thereof, or on one or more groupings of the data set 110 b; the processing power, bandwidth and/or other resource usage required to perform the particular computational analysis 125 a on the data set 110 b, on a portion thereof, or on one or more groupings of the data set 110 b; a number or multiplicity of sub-analyses, sub-activities or sub-operations that are required to be performed in order to execute the particular computational analysis 125 a on the data set 110 b, on a portion thereof, or on one or more groupings of the data set 110 b; and/or other compatibility criteria. The ability of the data set 110 b to meet one or more additional compatibility criteria may be determined based on the data set attribute data 118 and the computational analysis attribute data 122 a, for example.

In an embodiment, the matching engine 120 may evaluate the suitability and/or compatibility of the particular computational analysis 125 a to the converted data set 110 b by evaluating a subset of the data values 112 b of the data set 110 b. For example, the matching engine 120 may determine a measure of compatibility of the data set 110 b to the computational analysis 125 a on a per-grouping basis, e.g., by comparing respective data set attribute data indicative of each of one or more groupings of the data set 110 b with the computational analysis attribute data 122 a.

In an embodiment, the matching engine 120 may select the set of one or more groupings, and/or the matching engine 120 may select at least one data set attribute (corresponding to the one or more groupings) of the data set attribute data 118 whose information is to be compared with the conceptual analysis attribute data 122 a. In an embodiment, the matching engine 120 may select the set of one or more groupings and/or at least one data set attribute based on a data value included in a grouping of the data set 110 b that is not included in the comparison. Additionally or alternatively, the matching engine 120 may select the one or more groupings and/or the at least one data set attribute based on one or more other selection criteria, e.g., one or more respective attributes of the another grouping excluded from the comparison, a result of a previously performed comparison of the computational analysis 125 a, a result of another previously performed comparison of another computational analysis, or another suitable selection criteria.

The matching engine 120 may perform multiple comparisons corresponding to multiple, different groupings of the data set 110 b to determine the measure of compatibility of the data set 110 b and the particular computational analysis 125 a, in some scenarios. In an embodiment, at least some of the multiple comparisons performed by the matching engine 120 may be performed in parallel, e.g., by respective instances of the matching engine 120 executing in parallel. In an embodiment, at least some of the multiple comparisons may be performed sequentially by a single instance of the matching engine 120. Indeed, any one or more of these and other above discussed techniques may be used by the matching engine 120 to determine a measure of compatibility between the data set 110 b and a particular computational analysis (e.g., computational analysis 125 a).

In some embodiments, multiple computational analyses (e.g., two analyses, three analyses, or any multiple number of computational analyses) may be compared with the data set 110 b. In particular, computational analysis attribute data of multiple computational analyses (e.g., indications 122 a, 122 b, 122 c, 122 d) may be respectively compared to the data set attribute data 118 of the data set 110 b. In an embodiment, one or more of the multiple computational analyses may be automatically selected by the matching engine 120, manually selected by the user, or automatically selected by the matching engine 120 based partially on user input. For example, a second computational analysis 125 b may be selected based on a previously compared computational analysis (e.g., with the data set 110 b or with another data set). For instance, after comparing computational analysis attribute data 122 a to the data set attribute data 118, the matching engine 120 may automatically select an additional computational analysis attribute indication set 122 b for comparison with the data set attributes 118 based on the comparison of the analysis attribute data 122 a. Additionally or alternatively, the matching engine 120 may automatically select an additional computational analysis based on previously performed user actions. For example, the matching engine 120 may select an additional computational analysis 125 c for comparison based on computational analyses that were performed on data sets that were previously uploaded by the user.

In an embodiment, the user may provide input into the selection of a computational analysis (e.g., the analysis 125 d) whose computational analysis attribute data (e.g., the attribute data 122 d) is to be compared against data set attribute data 118. For example, the user may select an additional computational analysis 125 d to be compared with and/or performed on the data set 110 b after the user is presented with the results of the performance of the first computational analysis 125 a on the data set 110 b. In another example, the matching engine 120 may automatically select one or more additional computational analyses (e.g., the analysis 125 b or 125 c as discussed above) for possible comparisons, transmit indications of the additional analyses 125 b, 125 c to the user computer 105, and receive a user input indicating a user confirmation of which of the suggested additional computational analyses 125 b, 125 c are to be compared with and/or performed on the data set 110 b.

In an embodiment, the matching engine 120 may perform a comparison of (i) computation analysis attribute data 122 a-122 n of each of more than one computational analysis 125 a-125 n and (ii) data set attribute data 118 of the data set 110 b, and may generate a separate measure of compatibility for each of the compared computational analysis.

In an embodiment, the matching engine 120 may provide the measures of compatibility of the multiple compared analyses to a ranking engine 132 of the ADA system 102. The ranking engine 132 may compare the measures of compatibility to determine a ranking, e.g., from most compatible to least compatible computational analysis or vice versa, by assigning the computational analyses into bands of compatibility, or by determining one or more clusters of measures of compatibility.

The matching engine 120 may select at least a subset of the compared computational analyses to perform on the data set 110 b. In an embodiment, the matching engine 120 selects the at least the subset based on the ranking. For example, the matching engine 120 may select all compared computational analyses above a particular ranking or threshold for performance on the data set 110 b, or the matching engine 120 may select a subset of the compared computational analyses corresponding to a cluster of measures of compatibility. In some scenarios, all compared computational analyses may be selected to be performed, e.g., when all respective measures of compatibility meet a selection criterion, when a user indicates as such a priori, or as a default. In some scenarios, the at least the subset of compared computational analyses may be selected based on a resource or time required to the respective compared computational analysis on the data set 110 b, or based on a multiplicity of sub-operations or sub-analyses for the respective compared computational analysis. In an embodiment, the at least the subset of compared computational analysis is selected based on a parameter. In some scenarios, none of the compared computational analyses may be selected to be performed, and an indication of such may be presented to the user at the computer 105. The matching engine 120 may cause at least the selected subset of compared computational analyses to be automatically applied to, executed, operated, or performed on the data set 110 b or on a portion thereof (e.g., on one or more groupings of the data set 110 b).

The application, execution, operation or performance of the at least the selected subset of compared computational analyses on the data set 110 b may generate respective results for each performed computational analysis. Each respective result may include respective result content data. As such, the performance of a particular computational analysis on the data set 110 b may generate another different data set of different data points or data values, e.g., when the particular computational analysis is a heavyweight computational analysis.

In some embodiments, each respective result may also include information or data that is indicative of one or more contexts, characteristics or properties of the result content data, e.g., information indicative of attributes of the result content data (or “result attribute data”). For example, the result attribute data may identify one or more attributes of the result content data, and/or may describe one or more attributes of the result content data. The result attribute data may define one or more attributes of the result content data, in some embodiments, and/or may suggest one or more attributes of the result content data, in some embodiments. In some embodiments result attribute data may correspond to one or more attributes of the result content data. In some embodiments, the result attribute data may be associated with one or more attributes of the result content data.

Examples of result attributes may include a set of clusters, a domain (e.g., time, complex frequency), a range, and other attributes identifying properties and/or characteristics of the result content data. In an illustrative example, a regression analysis computational analysis may be performed on the data set 110 b. The set of result content data generated by the performance of the regression analysis may include a regression model expressed in a mathematical expression, and an identification of the independent and dependent variables of the regression model, and an example result attribute of each independent and dependent variable may be a respective level of confidence. Result attribute data may be represented by metadata, in an embodiment.

In some embodiments, the automated data analysis system 102 may include a presentation engine 135. The presentation engine 135 may be configured to indicate, at the user interface of the computing device 105 or at another user interface, the manner in which the original data set 110 a was interpreted by the pre-processor 115, in an embodiment. For example, the presentation engine 135 may cause information corresponding to the converted data set 110 b, the contents of the converted data set itself 110 b, or portions thereof to be presented or displayed.

In an embodiment, the presentation engine 135 may be configured to indicate, at the user interface of the computing device 105 or at another user interface, the at least the subset of the computational analyses that were applied to the converted data set 110 b. For example, the presentation engine 135 may cause identifications of one or more determined computational analyses to be presented, and/or the results of any executed computational analyses on the data set 110 b.

The presentation engine 135 may additionally be configured to select a view or visualization of the converted data set 110 b, and/or to select a view or visualization of the result content data of a computational analysis performed on the converted data set 110 b. Additionally, the presentation engine 135 may cause the views or visualizations to be presented at the user interface of the computing device 105. As previously discussed, a view or visualization of a data set may be a particular presentation of at least a portion of the data included in a data set. For example, a first view of the data set 110 b may include contextual labels and data values of three groupings of the data set 110 b arranged in a tabular format, e.g., “Bank Branch,” “Account Type,” and “Balance.” A second view of the data set 110 b may display at least some of the groupings in a pie chart format, e.g., one pie chart per Bank Branch showing the percentages of different Account Types at the particular Bank Branch. Yet a third view may describe the at least some of the groupings using natural language, e.g., “$X of the liabilities at Bank Branch N are attributed to Account Type Z.” Similarly, different views of at least portions of the result content data may respectively include a tabular format, a graphical format, a chart, natural language, etc. In some embodiments, a view or the visualization may require a lightweight computation to be performed.

The presentation engine 135 may be configured to select a particular view based on one or more view criteria. In some embodiments, the view may be a default view for a particular computational analysis, e.g., a pie chart and a bar chart may be default views for a cluster computational analysis. In some embodiments, a view may be selected based on attributes of the result of a performance of the particular computational analysis, e.g., the view may be selected at least partially based on result attribute data. For example, if a result attribute (as indicated by the result attribute data) is that the result content data values are distributed over equally spaced time intervals, a linear graph view may be selected to present the result context data.

In some embodiments, in addition to result attribute data, a view may be additionally or alternatively selected based on other view criteria, for example, a user selection or input for the particular data set or computational analysis, types of views the user has selected in the past, a type of computing device 105 or user interface on which the view is to be presented, and/or other view criteria. For example, a user may indicate whether he or she desires results of a regression analysis to be presented in a three-dimensional view or a flat view, or the matching engine 120 may automatically select a particular type of regression view based on the user's choice.

Additionally, in some embodiments, the presentation engine 135 and/or the matching engine 120 may determine the axes, dimensions, components, contents, etc., to be included on a particular graph view, at least in part based on the meaningfulness to the user in light of the contents and contexts of the result content data points or values. For example, based on the analysis of the converted data set 110 b, the ADA system 102 may determine that a line graph of grouping C vs. grouping D may provide more meaningful information than a line graph of grouping C vs. any other grouping. The ADA system 102 may determine that a pie chart of the data in groupings F, M and P is useful, whereas pie charts of other groupings are not informative or even nonsensical. The determination of the axes, dimensions, components, contents, etc., to be included on a particular view may be made by the ADA system 102 based on the data set attribute data 118, computational analysis attribute data 128, and/or on result attribute data, in an embodiment.

In an embodiment, to enable data analysis to be performed on the data set 110 b, the ADA system 102 includes a “hub” into which data set attribute data, computational analyses attribute data of one or more computational analyses, and (in some scenarios) result attribute data is input. In an embodiment, the hub includes at least portions of the matching engine 120, the ranking engine 132 and the presentation engine 135. Generally, the hub may determine compatibility between groupings, computational analyses, results, and/or views based on respective attribute data, and may automatically determine whether or not additional groupings, computational analyses, and/or views may be compatible or appropriate to compare, perform or generate as part of the comprehensive analysis of the data set 110 b. In an embodiment, the hub may assess compatibility between the data set 110 b and various computational analyses based on a set of rules or statements that characterize data sets that are compatible with each computational analysis, and that characterize the relationships between the compatible data sets and the each computational analysis. Typically, the set of rules or statements may be generated or determined from heuristics determined or derived from previously performed instances of computational analyses on various data sets, or from other sources.

Furthermore, while in FIG. 1 the ADA system 102 is shown as being communicatively connected with the user computer 105 via the network 108, other types of connections are possible. In some embodiments, at least a portion of the ADA system 102 may reside on the user computer 105. For example, at least a portion of the ADA system 102 may be a plug-in to an application executing on the user computer 105, such as database application. The database application may provide data from one or more rows and/or columns as input into the ADA system 102 for analysis, e.g., when a user selects a control within the database application. In another example, at least a portion of the ADA system 102 may a client or stand-alone application residing on the user computing device 105 that is in communicative connection with one or more other applications also residing on the computing device 105.

In some embodiments, the ADA 102 (whether executing on one or more remote computing devices as shown in FIG. 1, or executing at least partly on the user computing device 105) may be in communicative connection with other systems and/or applications. For example, the ADA system 102 may exchange messages with an application stored in a cloud or at a remote computing device, or the ADA system 102 may be a service that may be invoked by various other local or remote applications, e.g., via an application programming interface (API). In some embodiments, the ADA system 102 may provide information or data to another local or remote system or application, e.g., via an API, in response to a query, automatically to a receiving system or application that is identified a priori, to a receiving system or application that is specified in real-time, etc. For example, the ADA system 102 may provide result content data and/or result attribute data to another system or application, such as to a computing application, a natural language system, or a custom application. The ADA system 102 may provide an indication of the measure of compatibility between a particular computational analysis and the data set 110 b to another system and/or application. The ADA system 102 may additionally or alternatively provide other information or data to one or more local or remote systems or applications, such as an indication of at least a portion of the data set attribute data 118, an indication of at least a portion of the computational analysis attribute data 128, an indication of at least a portion of the computational analysis attribute data 128 corresponding to a specific computational analysis, an indication of the subset of computational analyses that were determined to be suitably compatible with the data set 110 a, heuristic information corresponding to a particular user, data set, and/or computational analysis, and other information or data.

To illustrate the concepts and features presented herein, an example scenario is provided. In this example, a data set is input into the automated data analysis system 102, and the ADA system 102 determines compatible computational analyses, performs the compatible computational analyses on the data set, and generates corresponding results. The results are generated and presented by the ADA system 102 in real-time, i.e., the results appear on the user interface within a second or two of entering the data set.

FIG. 3 is a reproduction of a portion of the contents of a sample input data set 202 used in the example scenario. The sample input data set 202 was obtained on Jan. 27, 2013 from http://lib.stat.cmu.edu/S/Harrell/data/descriptions/titanic.html, and includes data corresponding to passengers who sailed on the Titanic. Each row of the data set 202 corresponds to a different Titanic passenger. “P-Class” indicates the passenger's class of travel (i.e., first, second or third class).

FIGS. 4A and 4B illustrate screen shots or displays corresponding to data input at the automated data analysis system 102, according to an embodiment. In particular, FIG. 4A illustrates a screen shot of a data entry screen 205 of a user interface of the ADA system 102. The ADA system 102 causes the screen 205 to be displayed on a display device of the user computer 105, in an embodiment. The data entry screen 205 may include multiple user controls 208 a-208 f for facilitating a user to input data to the ADA system 102. For example, the entry screen 205 may include a text box 208 a into which natural language input may be entered, with a corresponding “enter” user control 208 b to signify when a user has finished entering all desired input into the text box 208 a. The entry screen 205 may include several selectable icons 208 c-208 f respectively corresponding to an extended keyboard 208 c, an image input 208 d, a data input 208 e, and a file upload 208 f. In an example scenario, a user selects the control 208 e to input data.

In response to the selection of the data input control 208 e, the ADA system 102 may cause the screen 209 shown in FIG. 4B to be displayed on the display device of the user computer 105, in an embodiment. The screen 209 may include one or more of the user controls 208 a-208 f from the previous screen 205, and may also include one or more other controls 210 a, 210 b to enable data input. For example, a user may indicate an input data set by entering its file name in the text box 208 a, or the user may select the upload user control 210 a to browse the user's file system and select particular a data set to upload. In the example scenario, though, the user cuts and pastes the contents of the data file 202 as a whole into the data input entry area 210 b. Once the user has finished entering data (via one of the controls 208 a, 210 a or 210 b or via another data entry control), the user may select the control 212 a to save the entered data, the control 212 b to have the system 102 analyze the entered data without saving it, or the control 212 c to have the system 102 save and analyze the entered data.

Portions of example output which may be presented after the automated data analysis system 102 has analyzed the input data 202, according to an embodiment, are shown in FIGS. 5A-5C. For example, the ADA system 102 may cause the screen 220 of FIG. 5A to be displayed on the display device of the user computer 105, in an embodiment. The screen 220 may indicate the manner in which the pre-processor 115 of the ADA system 102 interpreted the user input data 202 that was previously entered (e.g., that was previously entered via the screen 209). The screen 220 may include two portions 222 and 224, in an embodiment. A first portion 222 may indicate how the format of the input data 202 was interpreted by the ADA system 102. In the example scenario, the first portion 222 of the screen 220 indicates that the ADA system 102 interpreted the format of the material pasted into the data input entry area 210 b as a tabular input having four columns and 1313 rows. A second portion 224 of the screen 220 may indicate how the contents of the input data 202 were interpreted by the ADA system 102. That is, the second portion 224 may include a representation or view of a converted data set 225 that was generated by the ADA system 102 from the original data set 202. In this example scenario, the ADA system 102 has identified four groupings in the original data set 202, i.e., PClass, Age, Sex and Survived, and thus included the four groupings in the converted data set 225. Further, the ADA system 102 has generated respective data attribute sets (e.g., metadata) corresponding to each of the groupings PClass, Age, Sex and Survived, as well as for the entire converted data set 224 as a whole (although the data attributes are not shown on the screen 220). The screen 220 may additionally provide a user control 228 to enable the user to view the original data set 202, and the screen 220 may provide one or more user controls 230 a, 230 b to enable the user to change the view or presentation of the converted data set 225, such as by sort order, size of display, and other factors.

FIG. 5B-1 and FIG. 5B-2 illustrate a selected set of views 235-248 showing the results of lightweight computational analyses or visualizations that were determined by the ADA system 102 to be meaningful based on the analysis of the contexts and contents of the converted data set 225. Indeed, not only were the visualizations 235-248 selected by the ADA system 102, but the particular inputs to each visualization 235-248 and the axes, dimensions, and formats for presentation of each visualization were also determined and selected by the ADA system 102, e.g., based on at least the meaningfulness of the contexts and contents of the data set 225, as is discussed below.

In the example scenario, one of the visualizations or lightweight computational analyses that was performed on the data set 225 and that was determined by the ADA system 102 as including rich or useful information is a raw data plot 235 of the ages of passengers. The ADA system 102 determined that the raw data scatter plot 235 is a compatible and useful computational analysis to perform on the data set 225 as compared to at least some of the other possible computational analyses. For example, the ADA system 102 compared the metadata corresponding to attributes of “raw data scatter plot” with the metadata indicative of the data attributes of the converted data set 225. Based on this comparison, the measure of compatibility of the data set 225 and the “raw data scatter plot” computational analysis was determined to be relatively high as compared to the measures of compatibility of the data set 225 and at least some other computational analyses (e.g., word trees, bubble charts, and logarithm histograms).

Furthermore, the ADA system 102 determined that plotting the passenger ages in the raw data scatter plot was more meaningful than, for example, plotting passenger class or survival of all passengers in a raw data scatter plot. In particular, one of the computational analysis attributes of “raw data scatter plot” (as determined by heuristics and/or by other sources) indicates that performing a raw data scatter plot on a range of data values that is wider provides more meaningful results than performing the raw data scatter plot on a narrower range of data values. As such, the ADA system 102 examined the metadata of the groupings of the converted data set 225 and determined that the grouping PClass has a range of only three values (i.e., 1^(st) class, 2^(nd) class and 3^(rd) class), the grouping Sex has a range of only two values (i.e., female and male), and the grouping Survived has a range of only two values (i.e., 1 and 0). On the other hand, the grouping Age has a far wider range of values from approximately 0 to approximately 80. Accordingly, based on a comparison of the metadata corresponding to the data attributes of the groupings, the ADA system 102 determined that the grouping Age has the widest range of values, and therefore Age is the most compatible grouping on which to perform the computational analysis “raw data scatter plot.” Accordingly, the ADA system 102 performed a raw scatter plot on the grouping Age and presented the results in view 235.

A second visualization or lightweight computational analysis that the ADA system 102 determined to be compatible and useful to perform on the data set 225 is a linear histogram 238 showing the number of survivors/non-survivors vs. age. Similar to the first visualization, the ADA system 102 compared the metadata corresponding to attributes of “linear histogram” with the metadata indicative of the data attributes of the groupings of the converted data set 225, and the measure of compatibility of “linear histogram” was determined to be relatively high as compared to the measures of compatibility of other computational analyses (e.g., word trees, bubble charts, and logarithm histograms). Additionally, the ADA system 102 determined that, for the data set 225, number of survivors/non-survivors vs. age was more meaningful to perform and present than, for example, passenger class vs. age or sex vs. age. The ADA system 102 was able to make this determination in a manner similar to that discussed for the “raw data scatter plot” computational analysis, e.g., by comparing the data attribute data of each grouping with the information indicative of the attributes of “linear histogram” to determine the most compatible combination of groupings to use on the x and y axes of the linear histogram, and by comparing grouping attribute metadata and “linear histogram” attribute metadata.

Other example visualizations produced in this example scenario include label counts 240 by groupings (e.g., PClass and Sex), pie charts 242 of one grouping vs. another grouping (e.g., PClass vs. Age), basic or simple statistics 245, and basic or simple distributions 248. Typically, each visualization 235-248 may include one or more respective user controls 250 a-250 f via which a user may select a different view or arrangement of the analyzed data 225.

Furthermore, in this scenario, the set of displayed visualizations 235-248 represent a set of more compatible visualizations for the data set 225 as compared to other visualizations, as determined by the ADA system 102 based on comparing measures of compatibility. For example, the measures of compatibility of the visualizations 235-248 were more tightly clustered than other measures of compatibility of other visualizations (e.g., word trees, bubble charts, logarithmic histograms), and based on the clustering, the ADA system 102 selected the set of visualizations 235-248 to perform.

In addition to determining and performing a set of lightweight computational analyses 235-248, the ADA system 102 of the example scenario has also determined and performed a set of one or more heavyweight computational analyses that are compatible with the data set 225, one of which is illustrated by FIGS. 5C-1 and 5C-2 (reference 252). Similar to the lightweight computational analyses or visualizations 235-248, the heavyweight or complex computational analyses were determined by the ADA system 102 to be meaningful based on the analysis of the contexts and contents of the converted data set 225. Additionally, the particular inputs to the complex computational analyses, the axes, dimensions, and formats for presentation of their results were also determined and selected by the ADA system 102 based on at least the meaningfulness of the contexts and contents of the data set 225. However, unlike the lightweight computational analyses or visualizations, the heavyweight or complex computational analyses typically generate another, different set of data as an output, rather than merely present a view or visualization of the input data set 225.

FIGS. 5C-1 and 5C-2 illustrate one of these heavyweight computational analyses, i.e., a regression analysis 252. In particular, in the example scenario, the ADA system 102 determined (e.g., at least by comparing the computational analysis attribute data of the “regression analysis” computational analysis with the data set attribute data of the data set 225) that a regression analysis is a compatible computational analysis that would generate meaningful results when performed on the data set 225. The ADA system 102 caused the regression analysis to be performed on the data set 225, and the ADA system 102 caused the results 255 of the regression analysis to be presented to the user. The results 255 include, for example, a regression model and identities of the variables of the model (i.e., dependent variable “Survived” and independent variables “PClass,” “Age,” and “Sex”).

To determine the identities of the independent and dependent variables, again the ADA system 102 examined the data attribute metadata of groupings in comparison with the computational analysis attribute metadata. For example, multiple combinations of possible independent/dependent variables are possible for the data set 255, e.g., Survived=f(PClass, Age, Sex); PClass=f(Survived, Age, Sex); Age=f(Survived, PClass, Sex) and Sex=f(Survived, PClass, Age). By examining the metadata of groupings and determining correlations (if any) to metadata of other groupings, the ADA system 102 determined the combination of independent/dependent variables that was the most compatible with the metadata of regression analysis that characterizes variable interdependency. Based on at least this comparison (and on other comparisons), the ADA system 102 determined that Survived=f(PClass, Age, Sex) was more compatible with regression analysis than were any of the other combinations.

However, in the ADA system 102, the metadata examination for compatibility purposes need not be exhaustive across all possible combinations. For example, in the regression computational analysis example 252, the multiplicity of total sub-operations required to perform the regression analysis may be dynamically bounded based on the results of various sub-operations. For example, if the ADA system 102 initially determines that Survived depends on PClass, the ADA system 102 can forgo assessing whether or not PClass depends on Survive. Further, given the determination that Survived depends on PClass, the ADA system 102 may proceed with assessing whether or not Survived depends on any other variables, and may not perform further assessments on other combinations (e.g., does Age depend of PClass or does Age depend on Sex) if the correlations between Survived and the other variables are determined to be high or above a particular threshold.

In this example regression analysis scenario, the ADA system 102 also determined estimates and respective confidences 258 for the determined variables, which are shown in the view 258. Additionally, in the views 260 and 262, the ADA system 102 caused one or more conclusory or summary statements (e.g., using a natural language) that are based on the executed regression analysis 252 to be presented. As such, the ADA system 102 determined that, in addition to the regression analysis results 255, the particular views 258-262 of selected portions of the result content data 255 of the regression analysis would be meaningful and therefore caused the views 258-262 to be presented to the user.

The ADA system 102 additionally determined one or more other views 265, 268, 270 of the regression analysis computational analysis 252 whose identity and contents are meaningful for the data set 225. In particular, view 265 provides a one-way analysis of variance (ANOVA) of the data set 225, view 268 provides overall means and standard deviations and by passenger class in both a tabular and a graphical format, and view 270 provides an N-way ANOVA of age.

Similar to the lightweight computational analyses views 235-248, the views 255-270 associated with a complex computational analysis 252 may each include one or more user controls 272 a-272 e via which a user may select a different arrangement of output.

Of course, the example scenario described with respect to FIGS. 3, 4A-4B, 5A, 5B-1, 5B-2, 5C-1 and 5C-2 is illustrative only, and is not limiting. Other types of data sets may be input to the ADA system 102. Furthermore, other lightweight and heavyweight computational analyses may be compared with a data set to determine compatibility, e.g., one or more analyses listed in FIGS. 2A and 2B, or other computational analyses. Additionally, other suitable views may be determined and displayed based on the analysis of the input data.

FIG. 6 is a flow diagram of an example method 300 for automatically analyzing data sets. The method 300 may be implemented, at least partially, by the automated data analysis system 102 of FIG. 1, or by other suitable systems. In an embodiment, at least some of the method 300 may be implemented by the matching engine 120 of the ADA system 102.

The method 300 may include receiving information or data that is indicative of one or more attributes of a data set (block 302), e.g., the data set attribute data 118 of FIG. 1. The data set attribute data may be received, for example via a communication link, a bus, etc., at one or more computing devices which are configured to execute at least a portion of the method 300. In an embodiment, the one or more computing devices at which the data set attribute data is received may implement, at least partially, the automated data analysis system 102. The information or data corresponding to the data set attributes may comprise metadata, for example. The data set attribute data may be received in conjunction with receiving the data set and receiving other associated information (e.g., metadata corresponding to other aspects of the data set), or the data set attribute data may be received without receiving any other information corresponding to the data set. The data set may be directly provided by a user, may be generated by a module within the ADA system 102 (e.g., the pre-processor 115) or by another system, may be generated in response to a user input, etc.

The method 300 may include determining an identity of a particular computational analysis (block 305). A particular computational analysis may be automatically determined or selected by one or more computing devices, such as the one or more computing devices at which the data set attribute data was received (block 302). In some embodiments, the computational analysis may be selected at least partially based on a previously received user input, such as a specific user indication of the particular computational analysis, or one or more previous user actions. In some embodiments, the computational analysis may be selected based on at least part of the data set attribute data, on the identity of another computational analysis, and/or on a result of an execution of another computational analysis. In some embodiments, the computational analysis may be selected from a library of computational analyses that the ADA system 102 is configured to perform, e.g., by executing respective computer-executable instructions.

The data set attribute data may be compared (block 308) to computational analysis attribute data or information corresponding to the particular computational analysis (e.g., one of the sets of indications 122 a-122 n of the computational analysis attribute data 128 of FIG. 1). In some embodiments and/or scenarios, data set attribute data of a grouping of the data set may be compared to the computational analysis attribute data. In some embodiments and/or scenarios, data set attribute data for multiple groupings and/or for the data set as a whole may be compared to the computational analysis attribute data. The computational analysis attribute data may comprise metadata, in an embodiment.

The computational analysis attribute data may be obtained, for example, from a system that supports automated data analysis, e.g., from an “ADA support system.” The ADA support system may be included on the one or more computing devices executing the method 300, or may be included on one or more other computing devices. In an embodiment, the ADA support system may be integral with the ADA system 102, and in an embodiment, the ADA support system may be separate from but in communicative connection with the ADA system 102. In an embodiment, the computational analysis attribute data may stored on and obtained from one or more tangible, non-transitory data storage media or devices of the ADA support system, where the one or more tangible, non-transitory data storage media or devices are accessible to one or more computing devices executing the method 300, such as by a communication interface.

The method 300 may include determining a measure of compatibility (block 310) of at least a portion of the data set (e.g., one or more groupings of the data set) and the computational analysis. The determination (block 310) may be performed based on the comparison of the data set attribute data and the computational analysis attribute data (block 308). In an embodiment, the measure of compatibility may indicate a likelihood of generation of useful, meaningful, or statistically rich information when the computational analysis is performed on one or more groupings of the data set. In some embodiments, in addition to comparing data set attribute data and computational analysis attribute data, the measure of compatibility may be determined based on a resource required to perform the computational analysis on the data set or on a portion thereof, a time required to execute the computational analysis on the data set or on a portion thereof, a multiplicity of sub-analyses or sub-functions that are required to execute the computational analysis on the data set or a portion thereof, a parameter, and/or some other criteria.

If additional computational analyses are to be assessed for compatibility with the data set or a portion thereof (block 312), the method 300 may return to blocks 305-310 for each subsequent computational analysis. The identity of a subsequent computational analysis and/or at least a subset of the data set to which the subsequent computational analysis is to be compared may be determined, for example, by at least similar criteria used to select the initial computational analysis. In an embodiment, the identities of a fixed set of computational analyses are provided to the method 300 to use in determining a subsequent computational analysis.

In some embodiments, multiple instances of the blocks 305-310 of the method 300 may be performed in parallel, e.g., by multiple instances of a matching engine 120. In some instances, the multiple instances of the blocks 305-310 may be performed in parallel on data set attribute data corresponding to different groupings of the data set.

The method 300 may determine one or more computational analyses that are to be performed on at least one of the groupings of the data set (block 315). The indication determination 315 may be made based on the determined measures of compatibility (block 310), for example. In an embodiment, computational analyses having respective measures of compatibility that meet a boundary condition may be determined to be included in the one or more computational analyses that are to be performed on at least a portion of the data set. The one or more computational analyses that are to be performed on the data set may include all computational analyses that were compared against the data set (block 308), or may include a subset of the compared analyses.

In an embodiment, the boundary condition for determining the one or more computational analyses that are to be performed on at least a portion of the data set may be dynamically and automatically determined and generated for each data set. For example, the boundary condition may be determined based on a clustering of the computational analyses or of their respective measures of compatibilities, and/or the boundary condition may be based on a pre-defined threshold of suitability or compatibility. The boundary condition may be generated based on a range or diversity of types of the compared computational analyses, and/or based on a parameter. In an embodiment, in addition to one of the above criteria, determining the boundary condition and the one or more computational analyses that are to be performed may be further based on a user input or on a default setting.

The method 300 may include performing the one or more computational analyses on individual groupings, one or more sets of groupings, etc., of the data set (block 318), in an embodiment. The execution of each of the one or more computational analyses may be performed at least partially in parallel and/or at least partially in serial. Block 318 may include performing the same computation analysis multiple times on multiple different groupings or multiple different groupings of data.

The method 300 may cause indication(s) of one or more computational analyses to be presented at a user interface (block 320), along with an indication of their respective compatibility (e.g., incompatible with the data set, compatible with the data set, and/or relative degree of incompatibility or compatibility, such as previously discussed). In an embodiment, a set of computational analyses that were determined to be compatible with the data set may be presented, and, in some cases, the set of compatible computational analyses may be presented in conjunction with an indication of their respective measures of compatibility. In an embodiment, a set of computational analyses that were determined to be incompatible with the data set may be presented, and, in some cases, the set of incompatible computational analyses may be presented in conjunction with their respective measures of incompatibility. For example, a list of incompatible computational analyses may be presented along with their respective probabilities of incompatibility.

In an embodiment, respective result content data of the one or more computational analyses (whether compatible or incompatible) may be presented at the user interface, such as in one or more views. The method 300 may enable a user to change a view of the presented result content data, in an embodiment.

In some embodiments, the indications of the compatibilities or incompatibilities are not presented to the user. In some embodiments, the indication(s) of the one or more computational analyses and their respective indications of compatibility or incompatibility may be caused to be transmitted to another system, computing device, or application.

Although the method 300 is described herein as including blocks 302-320, the method 300 is not limited to including only blocks 302-320. In an embodiment, the method 300 may additionally or alternatively include any of the activities, actions, or functions of the ADA system 102 of FIG. 1, in an embodiment.

Any of the techniques described above, including the blocks described with reference to FIGS. 1 and 6, may be implemented using one or more processors that executes machine readable software or firmware instructions. Such computer program instructions may control the analysis of a computing system comprising one or more computing devices such as a desktop computer, a laptop computer, a tablet computer, a workstation, a server, a mainframe, a mobile phone (e.g., a smart phone), a telephone, a set top box, a PDA, a pager, a processing system of an electronic game, a processing system of a consumer electronics device, etc. The computing system may have one or more processors and one or more tangible, non-transitory memory devices in which the computer program instructions may be stored. The one or more processors are coupled to the one or more memory devices, and the one or more processors execute the computer program instructions. In various embodiments, computer program instructions may be written in any high level language such as the programming language used with MATHEMATICA® software systems, C, C++, C#, Java or the like or any low-level assembly or machine language. By storing computer program instructions in one or more memory devices of the computing system, the computing system is physically and/or structurally configured in accordance with the computer program instructions.

In an embodiment, the automated data analysis system 102 comprises such a computing system. The computing system may be a stand-alone device or a plurality of network devices arranged in a peer-to-peer, client-server, cloud computing or other suitable network configuration. In an embodiment, the computational analysis attribute data 128 of the ADA system 102 may be stored in a stand-alone storage device, in a memory of one or more computing devices of the ADA system 102, or in a plurality of physical storage devices having an external appearance as a single logical data storage entity.

While many methods and systems have been described herein as being implemented using one or more processors executing machine readable instructions, they may be implemented at least partially in hardware, and may be implemented by a variety of computing systems and devices. Thus, the method blocks and system blocks described herein may be implemented in one or more standard multi-purpose central processing units (CPUs), one or more special purpose processing units, or on specifically designed hardware such as an application-specific integrated circuit (ASIC) or other hard-wired device as desired. When implemented using a processor executing machine readable instructions, the machine readable instructions may be stored in any non-transitory, tangible computer readable storage medium such as on a magnetic disk, an optical disk (such as a compact disk (CD), a digital versatile disk (DVD)), a flash memory, a memory card, a memory stick, a RAM, a ROM, a database, DNA (Deoxyribonucleic Acid) or other biological or chemical media, etc.

The present disclosure has been described with reference to specific examples, which are intended to be illustrative only and not to be limiting. It will be apparent to those of ordinary skill in the art that changes, additions or deletions may be made to the disclosed examples without departing from the spirit and scope of the disclosure. The detailed description is to be construed as exemplary only and does not describe every possibly embodiment of the invention because describing every possible embodiment would be impractical, if not impossible. Numerous alternative embodiments could be implemented, using either current technology or technology developed after the filing date of this patent, which would still fall within the scope of this application.

Thus, many modifications and variations may be made in the techniques and systems described and illustrated herein without departing from the spirit and scope of the present invention. Accordingly, it should be understood that the methods and systems described herein are illustrative only and are not limiting upon the scope of the invention. 

What is claimed:
 1. A system for automatically analyzing structured data sets, comprising: one or more processors; and one or more tangible, non-transitory computer readable storage devices coupled to the one or more processors, the one or more tangible, non-transitory computer readable storage devices storing: a structured data set to be analyzed; respective sets of machine readable instructions corresponding to computer executable computational analyses among a plurality of computer executable computational analyses, wherein the respective sets of machine readable instructions, when executed by the one or more processors, cause the one or more processors to perform respective computer executable computational analyses; computational analysis attribute data corresponding to the plurality of computer executable computational analyses, the computational analysis attribute data including, for each computer executable computational analysis, one or more respective attributes indicating respective characteristics of data required or preferred for the structured data set to be considered compatible with being an object of a performance of the each computer executable computational analysis; and further machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: determine one or more measures of compatibility between the structured data set and the one or more particular computer executable computational analyses using i) computational analysis attribute data corresponding to one or more particular computer executable computational analyses among the plurality of computational analyses, and ii) data set attribute data indicative of one or more characteristics of the structured data set, select a set of one or more computer executable computational analyses from the plurality of computer executable computational analyses using one or more measures of compatibility, the selected set of the one or more computer executable computational analyses corresponding to one or more candidate computer executable computational analyses for performing on at least a portion of the structured data set; and perform one or more computer executable computational analyses from the selected set on at least one of i) the structured data set, or ii) one or more portions of the structured data set.
 2. The system of claim 1, wherein the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: analyze the structured data set to generate the data set attribute data.
 3. The system of claim 2, wherein the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: analyze the structured data set to generate the data set attribute data without a priori knowledge of a format of the structured data set.
 4. The system of claim 2, wherein: the structured data set is in a tabular format including rows, columns, and headers; the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: analyze the headers to generate at least some of the data set attribute data.
 5. The system of claim 2, wherein the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to analyze the structured data set to: identify a plurality of groupings of data within the data set.
 6. The system of claim 5, wherein the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to analyze the structured data set to: determine respective data set attribute data specific to respective groupings of data.
 7. The system of claim 5, wherein: the structured data set is in a tabular format including rows and columns; at least some determined groupings correspond to at least one of i) columns of the structured data set, and ii) rows of the structured data set.
 8. The system of claim 1, wherein the data set attribute data comprises one or more of: a type of data within a structural grouping of the structured data set; an indication of whether data values in the structural grouping are serially correlated; an indication of whether all of the data values in the structural grouping are of a same length; an indication of whether an interval between successive data values in the structural grouping is constant; an indication of whether data values in the structural grouping are randomly distributed; an indication of whether data values in the structural grouping are uniformly distributed; and a range of the data values included in the structural grouping.
 9. The system of claim 1, wherein the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: perform one or more comparisons of i) at least some of the computational analysis attribute data, and ii) at least some of the data set attribute data; and determine at least one measure of compatibility between the structured data set and the one or more particular computer executable computational analyses using the one or more comparisons.
 10. The system of claim 1, wherein the computational analysis attribute data one of the computer executable computational analyses comprises at least one of: information indicating one or more data set attributes whose presence is necessary to be compatible with the one computer executable computational analysis; and information indicating one or more data set attributes whose presence is typical of data compatible with the one computer executable computational analysis.
 11. The system of claim 1, wherein the computational analysis attribute data one of the computer executable computational analyses comprises at least one of: a function, wherein at least a portion of the data set attribute data is an input to the function, and wherein an output of the function is indicative of a measure of compatibility between the data set and the one computer executable computational analysis; and a parametric attribute indicating a characteristic of data that is compatible with the one computer executable computational analysis.
 12. The system of claim 1, wherein the computational analysis attribute data one of the computer executable computational analyses comprises at least one of: an indication of a length of time to perform the one computer executable computational analysis as a function of an amount of input data; one or more parameters required as input to the one computer executable computational analysis; a required data type of input to the one computer executable computational analysis; a linguistic form of a required parameter or input to the one computer executable computational analysis; and a data type of an output generated by execution of the one computer executable computational analysis.
 13. The system of claim 1, wherein the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to, for one of the computer executable computational analyses: determine one or more resource usage criteria corresponding to the one computer executable computational analysis, the resource usage criteria including at least one of: one or more respective amounts of time required to execute the one computer executable computational analysis on one or more groupings of data within the data set, one or more measures of processing power required to execute the one computer executable computational analysis on the one or more groupings of data within the data set, one or more measures of processing bandwidth required to execute the one computer executable computational analysis on the one or more groupings of data within the data set, respective numbers of sub-operations of the one computer executable computational analysis required to execute the one computer executable computational analysis on the one or more groupings of data within the data set; and determine one or more measures of compatibility between the structured data set and the one computer executable computational analysis using the one or more resource usage criteria.
 14. The system of claim 1, wherein the respective sets of machine readable instructions includes one or more sets of machine readable instructions that, when executed by the one or more processors, cause the one or more processors to perform one or more of: a mathematical integration, a mathematical differentiation, a Fourier analysis, and a regression analysis.
 15. The system of claim 1, wherein: performance one of the computer executable computational analyses generates result content data; and the one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: select a view of at least a portion of the result content data, and generate display data that, when displayed on a display device, shows the view of the at least the portion of the result content data.
 16. The system of claim 15, wherein one or more tangible, non-transitory computer readable storage devices further store machine readable instructions that, when executed by the one or more processors, cause the one or more processors to: select the view of the at least a portion of the result content data using user input data received via a user interface device.
 17. A method for automatically analyzing data sets, the method comprising: determining, at one or more processors, one or more measures of compatibility between i) a structured data set to be analyzed and ii) one or more computer executable computational analyses using a) computational analysis attribute data corresponding to one or more computer executable computational analyses among a plurality of computational analyses, and b) data set attribute data indicative of one or more characteristics of the structured data set, wherein one or more tangible, non-transitory computer readable storage devices, coupled to the one or more processors, store: respective sets of machine readable instructions corresponding to the computer executable computational analyses, wherein the respective sets of machine readable instructions, when executed by the one or more processors, cause the one or more processors to perform the respective computer executable computational analyses, and computational analysis attribute data corresponding to the computer executable computational analyses, the computational analysis attribute data including, for each computer executable computational analysis, one or more respective attributes indicating respective characteristics of data required or preferred for the structured data set to be considered compatible with being an object of a performance of the each computer executable computational analysis; selecting, at the one or more processors, a set of one or more computer executable computational analyses from the plurality of computer executable computational analyses using one or more measures of compatibility, the selected set of the one or more computer executable computational analyses corresponding to one or more candidate computer executable computational analyses for performing on at least a portion of the structured data set; and performing, at the one or more processors, one or more computer executable computational analyses from the selected set on at least one of i) the structured data set, or ii) one or more portions of the structured data set.
 18. The method of claim 17, further comprising: analyzing, at the one or more processors, the structured data set to generate the data set attribute data.
 19. The method of claim 18, further comprising: analyzing, at the one or more processors, the structured data set to generate the data set attribute data without a priori knowledge of a format of the structured data set.
 20. The method of claim 18, wherein: the structured data set is in a tabular format including rows, columns, and headers; the method further comprises: analyzing, at the one or more processors, the headers to generate at least some of the data set attribute data.
 21. The method of claim 18, further comprising: identifying, at the one or more processors, a plurality of groupings of data within the data set.
 22. The method of claim 21, further comprising: determining, at the one or more processors, respective data set attribute data specific to respective groupings of data.
 23. The method of claim 21, wherein: the structured data set is in a tabular format including rows and columns; at least some determined groupings correspond to at least one of i) columns of the structured data set, and ii) rows of the structured data set.
 24. The method of claim 17, wherein the data set attribute data comprises one or more of: a type of data within a structural grouping of the structured data set; an indication of whether data values in the structural grouping are serially correlated; an indication of whether all of the data values in the structural grouping are of a same length; an indication of whether an interval between successive data values in the structural grouping is constant; an indication of whether data values in the structural grouping are randomly distributed; an indication of whether data values in the structural grouping are uniformly distributed; and a range of the data values included in the structural grouping.
 25. The method of claim 17, further comprising: performing, at the one or more processors, one or more comparisons of i) at least some of the computational analysis attribute data, and ii) at least some of the data set attribute data; and determining, at the one or more processors, at least one measure of compatibility between the structured data set and the one or more particular computer executable computational analyses using the one or more comparisons.
 26. The method of claim 17, wherein the computational analysis attribute data one of the computer executable computational analyses comprises at least one of: information indicating one or more data set attributes whose presence is necessary to be compatible with the one computer executable computational analysis; and information indicating one or more data set attributes whose presence is typical of data compatible with the one computer executable computational analysis.
 27. The method of claim 17, wherein the computational analysis attribute data one of the computer executable computational analyses comprises at least one of: a function, wherein at least a portion of the data set attribute data is an input to the function, and wherein an output of the function is indicative of a measure of compatibility between the data set and the one computer executable computational analysis; and a parametric attribute indicating a characteristic of data that is compatible with the one computer executable computational analysis.
 28. The method of claim 17, wherein the computational analysis attribute data one of the computer executable computational analyses comprises at least one of: an indication of a length of time to perform the one computer executable computational analysis as a function of an amount of input data; one or more parameters required as input to the one computer executable computational analysis; a required data type of input to the one computer executable computational analysis; a linguistic form of a required parameter or input to the one computer executable computational analysis; and a data type of an output generated by execution of the one computer executable computational analysis.
 29. The method of claim 17, further comprising, for one of the computer executable computational analyses: determining, at the one or more processors, one or more resource usage criteria corresponding to the one computer executable computational analysis, the resource usage criteria including at least one of: one or more respective amounts of time required to execute the one computer executable computational analysis on one or more groupings of data within the data set, one or more measures of processing power required to execute the one computer executable computational analysis on the one or more groupings of data within the data set, one or more measures of processing bandwidth required to execute the one computer executable computational analysis on the one or more groupings of data within the data set, respective numbers of sub-operations of the one computer executable computational analysis required to execute the one computer executable computational analysis on the one or more groupings of data within the data set; and determining, at the one or more processors, one or more measures of compatibility between the structured data set and the one computer executable computational analysis using the one or more resource usage criteria.
 30. The method of claim 17, wherein the respective sets of machine readable instructions includes one or more sets of machine readable instructions that, when executed by the one or more processors, cause the one or more processors to perform one or more of: a mathematical integration, a mathematical differentiation, a Fourier analysis, and a regression analysis.
 31. The method of claim 17, wherein: performance one of the computer executable computational analyses generates result content data; and the method further comprises: selecting, at the one or more processors, a view of at least a portion of the result content data, and generating, at the one or more processors, display data that, when displayed on a display device, shows the view of the at least the portion of the result content data.
 32. The method of claim 31, further comprising: selecting, at the one or more processors, the view of the at least a portion of the result content data using user input data received via a user interface device.
 33. A tangible, non-transitory computer readable storage medium, or media, storing: respective sets of machine readable instructions corresponding to a plurality of computer executable computational analyses, wherein each set of machine readable instructions, when executed by one or more processors, cause the one or more processors to perform the respective computer executable computational analysis; computational analysis attribute data corresponding to the computer executable computational analyses, the computational analysis attribute data including, for each computer executable computational analysis, one or more respective attributes indicating respective characteristics of data required or preferred for the structured data set to be considered compatible with being an object of a performance of the each computer executable computational analysis; wherein the tangible, non-transitory computer readable storage medium, or media, stores further machine readable instructions that, when executed by one or more processors, cause the one or more processors to: determine one or more measures of compatibility between i) a structured data set to be analyzed and ii) one or more computer executable computational analyses using a) computational analysis attribute data corresponding to one or more particular computer executable computational analyses among the set of computational analyses, and b) data set attribute data indicative of one or more characteristics of the structured data set, select a set of one or more computer executable computational analyses from the computer executable computational analyses using one or more measures of compatibility, the selected set of the one or more computer executable computational analyses corresponding to one or more candidate computer executable computational analyses for performing on at least a portion of the structured data set, and perform one or more computer executable computational analyses from the selected set on at least one of i) the structured data set, or ii) one or more portions of the structured data set. 